#ifdef ARCH_ia32

//********************************************************************
// ATA LOW LEVEL I/O DRIVER -- ATAIOREG.C
//
// by Hale Landis (www.ata-atapi.com)
//
// There is no copyright and there are no restrictions on the use
// of this ATA Low Level I/O Driver code.  It is distributed to
// help other programmers understand how the ATA device interface
// works and it is distributed without any warranty.  Use this
// code at your own risk.
//
// This code is based on the ATA-2, ATA-3 and ATA-4 standards and
// on interviews with various ATA controller and drive designers.
//
// This code has been run on many ATA (IDE) drives and
// MFM/RLL controllers.  This code may be a little
// more picky about the status it sees at various times.  A real
// BIOS probably would not check the status as carefully.
//
// Compile with one of the Borland C or C++ compilers.
//
// This C source contains the main body of the driver code:
// Determine what devices are present, issue ATA Soft Reset,
// execute Non-Data, PIO data in and PIO data out commands.
//********************************************************************


#include "ataio.h"

#define DEBUG_REG 0x00  // not zero for debug
                        // 0x01 trace the interrupt flag

//*************************************************************
//
// ATAPI command packet,
// atapi register data,
// atapi delay flag,
// config information,
// slow transfer flag,
// incompatible flags.
//
//*************************************************************
/*
unsigned char reg_atapi_cp_data[16];
int reg_atapi_cp_size;

int reg_atapi_delay_flag;

unsigned char reg_atapi_reg_fr;  // see reg_packet()
unsigned char reg_atapi_reg_sc;  // see reg_packet()
unsigned char reg_atapi_reg_sn;  // see reg_packet()
unsigned char reg_atapi_reg_dh;  // see reg_packet()

long reg_buffer_size;

struct REG_CMD_INFO reg_cmd_info;

int reg_config_info[2];

void ( * reg_drq_block_call_back ) ( struct REG_CMD_INFO * );

long reg_slow_xfer_flag;

int reg_incompat_flags;
*/
//*************************************************************
//
// reg_wait_poll() - wait for interrupt or poll for BSY=0
//
//*************************************************************

static void reg_wait_poll( int we, int pe );

static void reg_wait_poll( int we, int pe )

{
   unsigned char status;

   // Wait for interrupt -or- wait for not BUSY -or- wait for time out.

   if ( we && ata->int_use_intr_flag )
   {
      trc_llt( 0, 0, TRC_LLT_WINT );
//printf("wait 4 intr... ");
      while ( 1 )
      {
         if ( ata->int_intr_flag )                // interrupt ?
         {
#warning sema
             // driver is threaded, so just yeld
             ATA_YIELD();

            trc_llt( 0, 0, TRC_LLT_INTRQ );  // yes
            if ( ata->int_bmide_addr )
            {
               trc_llt( 0, ata->int_bm_status, TRC_LLT_R_BM_SR );
            }
            status = ata->int_ata_status;         // get status
            (void) status; // what for?
            trc_llt( CB_STAT, status, TRC_LLT_INB );
            if ( ata->int_bmide_addr )
            {
               trc_llt( 0, 0x04, TRC_LLT_W_BM_SR );
            }
            break;
         }
         if ( tmr_chk_timeout() )            // time out ?
         {
            trc_llt( 0, 0, TRC_LLT_TOUT );   // yes
            ata->reg_cmd_info.to = 1;
            ata->reg_cmd_info.ec = we;
            trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
            break;
         }
      }
   }
   else
   {
      trc_llt( 0, 0, TRC_LLT_PNBSY );
//printf("poll... ");
      while ( 1 )
      {
         status = pio_inbyte( CB_ASTAT );       // poll for not busy
         if ( ( status & CB_STAT_BSY ) == 0 )
            break;
         if ( tmr_chk_timeout() )               // time out yet ?
         {
            trc_llt( 0, 0, TRC_LLT_TOUT );
            ata->reg_cmd_info.to = 1;
            ata->reg_cmd_info.ec = pe;
            trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
            break;
         }
      }
   }
//printf("end poll... ");
   #if DEBUG_REG & 0x01
      trc_llt( 0, ata->int_intr_cntr, TRC_LLT_DEBUG );  // for debugging
   #endif

   // Reset the interrupt flag.

   if ( ata->int_intr_flag > 1 )      // extra interrupt(s) ?
      ata->reg_cmd_info.failbits |= FAILBIT15;
   ata->int_intr_flag = 0;
}

//*************************************************************
//
// reg_config() - Check the host adapter and determine the
//                number and type of drives attached.
//
// This process is not documented by any of the ATA standards.
//
// Infomation is returned by this function is in
// reg_config_info[] -- see ATAIO.H.
//
//*************************************************************

int reg_config( void )

{
   int numDev = 0;
   unsigned char dev75;
   unsigned char sc;
   unsigned char sn;
   unsigned char cl;
   unsigned char ch;
   unsigned char st;
   unsigned char devCtrl;

   // compute the 1ms, 1us and 500ns delay counts - the number of I/O reads
   // required to get an approximately 1ms, 1us and 500ns delay.

   tmr_get_delay_counts();

   // determine value of Device (Drive/Head) register bits 7 and 5

   dev75 = 0;                    // normal value
   if ( ata->reg_incompat_flags & REG_INCOMPAT_DEVREG )
      dev75 = CB_DH_OBSOLETE;    // obsolete value

   // setup register values

   devCtrl = CB_DC_HD15 | ( ata->int_use_intr_flag ? 0 : CB_DC_NIEN );

   // mark start of config in low level trace

   trc_llt( 0, 0, TRC_LLT_S_CFG );

   // reset Bus Master Error bit

   sub_writeBusMstrStatus( BM_SR_MASK_ERR );

   // assume there are no devices

   ata->reg_config_info[0] = REG_CONFIG_TYPE_NONE;
   ata->reg_config_info[1] = REG_CONFIG_TYPE_NONE;

   // set up Device Control register

   pio_outbyte( CB_DC, devCtrl );

   // lets see if there is a device 0

   pio_outbyte( CB_DH, CB_DH_DEV0 | dev75 );
   ATA_DELAY();
   pio_outbyte( CB_SC, 0x55 );
   pio_outbyte( CB_SN, 0xaa );
   pio_outbyte( CB_SC, 0xaa );
   pio_outbyte( CB_SN, 0x55 );
   pio_outbyte( CB_SC, 0x55 );
   pio_outbyte( CB_SN, 0xaa );
   sc = pio_inbyte( CB_SC );
   sn = pio_inbyte( CB_SN );
   if ( ( sc == 0x55 ) && ( sn == 0xaa ) )
      ata->reg_config_info[0] = REG_CONFIG_TYPE_UNKN;

   // lets see if there is a device 1

   pio_outbyte( CB_DH, CB_DH_DEV1 | dev75 );
   ATA_DELAY();
   pio_outbyte( CB_SC, 0x55 );
   pio_outbyte( CB_SN, 0xaa );
   pio_outbyte( CB_SC, 0xaa );
   pio_outbyte( CB_SN, 0x55 );
   pio_outbyte( CB_SC, 0x55 );
   pio_outbyte( CB_SN, 0xaa );
   sc = pio_inbyte( CB_SC );
   sn = pio_inbyte( CB_SN );
   if ( ( sc == 0x55 ) && ( sn == 0xaa ) )
      ata->reg_config_info[1] = REG_CONFIG_TYPE_UNKN;

   // quit if no devices found

   if ( ( ata->reg_config_info[0] == REG_CONFIG_TYPE_NONE )
        &&
        ( ata->reg_config_info[1] == REG_CONFIG_TYPE_NONE )
      )
   {
      trc_llt( 0, 0, TRC_LLT_E_CFG );
      return numDev;    // no devices found
   }

   // now we think we know which devices, if any are there,
   // so lets try a soft reset (ignoring any errors).

   pio_outbyte( CB_DH, CB_DH_DEV0 | dev75 );
   ATA_DELAY();
   reg_reset( 0, 0 );

   // lets check device 0 again, is device 0 really there?
   // is it ATA or ATAPI?

   pio_outbyte( CB_DH, CB_DH_DEV0 | dev75 );
   ATA_DELAY();
   sc = pio_inbyte( CB_SC );
   sn = pio_inbyte( CB_SN );
   st = pio_inbyte( CB_STAT );
   if ( st == 0x7f )
   {
      ata->reg_config_info[0] = REG_CONFIG_TYPE_NONE;
   }
   else
   if ( ( sc == 0x01 ) && ( sn == 0x01 ) )
   {
      // yep, there is a device, what kind is it?
      numDev ++ ;
      cl = pio_inbyte( CB_CL );
      ch = pio_inbyte( CB_CH );
      if ( ( ( cl == 0x14 ) && ( ch == 0xeb ) )       // PATAPI
           ||
           ( ( cl == 0x69 ) && ( ch == 0x96 ) )       // SATAPI
         )
      {
         ata->reg_config_info[0] = REG_CONFIG_TYPE_ATAPI;
      }
      else
      if ( ( ( cl == 0x00 ) && ( ch == 0x00 ) )     // PATA
           ||
           ( ( cl == 0x3c ) && ( ch == 0xc3 ) )     // SATA
         )
      {
         ata->reg_config_info[0] = REG_CONFIG_TYPE_ATA;
      }
   }

   // lets check device 1 again, is device 1 really there?
   // is it ATA or ATAPI?

   pio_outbyte( CB_DH, CB_DH_DEV1 | dev75 );
   ATA_DELAY();
   sc = pio_inbyte( CB_SC );
   sn = pio_inbyte( CB_SN );
   st = pio_inbyte( CB_STAT );
   if ( st == 0x7f )
   {
      ata->reg_config_info[1] = REG_CONFIG_TYPE_NONE;
   }
   else
   if ( ( sc == 0x01 ) && ( sn == 0x01 ) )
   {
      // yep, there is a device, what kind is it?
      numDev ++ ;
      cl = pio_inbyte( CB_CL );
      ch = pio_inbyte( CB_CH );
      if ( ( ( cl == 0x14 ) && ( ch == 0xeb ) )       // PATAPI
           ||
           ( ( cl == 0x69 ) && ( ch == 0x96 ) )       // SATAPI
         )
      {
         ata->reg_config_info[1] = REG_CONFIG_TYPE_ATAPI;
      }
      else
      if ( ( ( cl == 0x00 ) && ( ch == 0x00 ) )     // PATA
           ||
           ( ( cl == 0x3c ) && ( ch == 0xc3 ) )     // SATA
         )
      {
         ata->reg_config_info[1] = REG_CONFIG_TYPE_ATA;
      }
   }

   // If possible, select a device that exists

   if ( ata->reg_config_info[1] != REG_CONFIG_TYPE_NONE )
   {
      pio_outbyte( CB_DH, CB_DH_DEV1 | dev75 );
      ATA_DELAY();
   }
   if ( ata->reg_config_info[0] != REG_CONFIG_TYPE_NONE )
   {
      pio_outbyte( CB_DH, CB_DH_DEV0 | dev75 );
      ATA_DELAY();
   }

   // BMIDE Error=1?

   if ( sub_readBusMstrStatus() & BM_SR_MASK_ERR )
   {
      ata->reg_cmd_info.ec = 78;                  // yes
      trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
   }

   // mark end of config in low level trace

   trc_llt( 0, 0, TRC_LLT_E_CFG );

   // return the number of devices found

   return numDev;
}

//*************************************************************
//
// reg_reset() - Execute a Software Reset.
//
// See ATA-2 Section 9.2, ATA-3 Section 9.2, ATA-4 Section 8.3.
//
//*************************************************************

int reg_reset( int skipFlag, int devRtrn )

{
   unsigned char dev75;
   unsigned char sc;
   unsigned char sn;
   unsigned char status;
   unsigned char devCtrl;

   // determine value of Device (Drive/Head) register bits 7 and 5

   dev75 = 0;                    // normal value
   if ( ata->reg_incompat_flags & REG_INCOMPAT_DEVREG )
      dev75 = CB_DH_OBSOLETE;    // obsolete value

   // setup register values

   devCtrl = CB_DC_HD15 | ( ata->int_use_intr_flag ? 0 : CB_DC_NIEN );

   // mark start of reset in low level trace

   trc_llt( 0, 0, TRC_LLT_S_RST );

   // reset Bus Master Error bit

   sub_writeBusMstrStatus( BM_SR_MASK_ERR );

   // Reset error return data.

   sub_zero_return_data();
   ata->reg_cmd_info.flg = TRC_FLAG_SRST;
   ata->reg_cmd_info.ct  = TRC_TYPE_ASR;

   // initialize the command timeout counter

   tmr_set_timeout();

   // Set and then reset the soft reset bit in the Device Control
   // register.  This causes device 0 be selected.

   if ( ! skipFlag )
   {
      // set SRST=1
      pio_outbyte( CB_DC, devCtrl | CB_DC_SRST );
      ATA_DELAY();      // for trace of Alternate Status
      // delay ~10us
      tmr_delay_1us( 10L );
      // set SRST=0
      pio_outbyte( CB_DC, devCtrl );
      ATA_DELAY();      // for trace of Alternate Status
   }
   ATAPI_DELAY( 0 );
   ATAPI_DELAY( 1 );

   // If there is a device 0, wait for device 0 to set BSY=0.

   if ( ata->reg_config_info[0] != REG_CONFIG_TYPE_NONE )
   {
      trc_llt( 0, 0, TRC_LLT_PNBSY );
      while ( 1 )
      {
         status = pio_inbyte( CB_STAT );
         if ( ( status & CB_STAT_BSY ) == 0 )
            break;
         if ( tmr_chk_timeout() )
         {
            trc_llt( 0, 0, TRC_LLT_TOUT );
            ata->reg_cmd_info.to = 1;
            ata->reg_cmd_info.ec = 1;
            trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
            break;
         }
      }
   }

   // Check that drive 0 has valid BSY=0 status

   if ( ata->reg_cmd_info.ec == 0 )
   {
      status = pio_inbyte( CB_STAT );
      if ( ( status == 0x7f ) || ( status & CB_STAT_BSY ) )
      {
         ata->reg_cmd_info.ec = 1;
         trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
      }
   }

   // If there is a device 1, wait until device 1 allows
   // register access.

   if ( ata->reg_config_info[1] != REG_CONFIG_TYPE_NONE )
   {
      trc_llt( 0, 0, TRC_LLT_PNBSY );
      while ( 1 )
      {
         pio_outbyte( CB_DH, CB_DH_DEV1 | dev75 );
         ATA_DELAY();
         sc = pio_inbyte( CB_SC );
         sn = pio_inbyte( CB_SN );
         if ( ( sc == 0x01 ) && ( sn == 0x01 ) )
            break;
         if ( tmr_chk_timeout() )
         {
            trc_llt( 0, 0, TRC_LLT_TOUT );
            ata->reg_cmd_info.to = 1;
            ata->reg_cmd_info.ec = 2;
            trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
            break;
         }
      }

      // Check if drive 1 has valid BSY=0 status

      if ( ata->reg_cmd_info.ec == 0 )
      {
         status = pio_inbyte( CB_STAT );
         if ( ( status == 0x7f ) || ( status & CB_STAT_BSY ) )
         {
            ata->reg_cmd_info.ec = 3;
            trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
         }
      }
   }

   // RESET_DONE:

   // We are done but now we must select the device the caller
   // requested before we trace the command.  This will cause
   // the correct data to be returned in ata->reg_cmd_info.

   pio_outbyte( CB_DH, ( devRtrn ? CB_DH_DEV1 : CB_DH_DEV0 ) | dev75 );
   ATA_DELAY();
   sub_trace_command();

   // If possible, select a device that exists

   if ( ata->reg_config_info[1] != REG_CONFIG_TYPE_NONE )
   {
      pio_outbyte( CB_DH, CB_DH_DEV1 | dev75 );
      ATA_DELAY();
   }
   if ( ata->reg_config_info[0] != REG_CONFIG_TYPE_NONE )
   {
      pio_outbyte( CB_DH, CB_DH_DEV0 | dev75 );
      ATA_DELAY();
   }

   // BMIDE Error=1?

   if ( sub_readBusMstrStatus() & BM_SR_MASK_ERR )
   {
      ata->reg_cmd_info.ec = 78;                  // yes
      trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
   }

   // mark end of reset in low level trace

   trc_llt( 0, 0, TRC_LLT_E_RST );

   // All done.  The return values of this function are described in
   // ATAIO.H.

   if ( ata->reg_cmd_info.ec )
      return 1;
   return 0;
}

//*************************************************************
//
// exec_non_data_cmd() - Execute a non-data command.
//
// Note special handling for Execute Device Diagnostics
// command when there is no device 0.
//
// See ATA-2 Section 9.5, ATA-3 Section 9.5,
// ATA-4 Section 8.8 Figure 12.  Also see Section 8.5.
//
//*************************************************************

static int exec_non_data_cmd( int dev );

static int exec_non_data_cmd( int dev )

{
   unsigned char dev75;
   unsigned char secCnt;
   unsigned char secNum;
   unsigned char status;
   int polled = 0;

   // determine value of Device (Drive/Head) register bits 7 and 5

   dev75 = 0;                    // normal value
   if ( ata->reg_incompat_flags & REG_INCOMPAT_DEVREG )
      dev75 = CB_DH_OBSOLETE;    // obsolete value

   // mark start of ND cmd in low level trace

   trc_llt( 0, 0, TRC_LLT_S_ND );

   // reset Bus Master Error bit

   sub_writeBusMstrStatus( BM_SR_MASK_ERR );

   // Set command time out.

   tmr_set_timeout();

   // PAY ATTENTION HERE
   // If the caller is attempting a Device Reset command, then
   // don't do most of the normal stuff.  Device Reset has no
   // parameters, should not generate an interrupt and it is the
   // only command that can be written to the Command register
   // when a device has BSY=1 (a very strange command!).  Not
   // all devices support this command (even some ATAPI devices
   // don't support the command.

   if ( ata->reg_cmd_info.cmd != CMD_DEVICE_RESET )
   {
      // Select the drive - call the sub_select function.
      // Quit now if this fails.

      if ( sub_select( dev ) )
      {
         sub_trace_command();
         trc_llt( 0, 0, TRC_LLT_E_ND );
         return 1;
      }

      // Set up all the registers except the command register.

      sub_setup_command();

      // For interrupt mode, install interrupt handler.

      int_save_int_vect();
   }

   // Start the command by setting the Command register.  The drive
   // should immediately set BUSY status.

   pio_outbyte( CB_CMD, ata->reg_cmd_info.cmd );

   // Waste some time by reading the alternate status a few times.
   // This gives the drive time to set BUSY in the status register on
   // really fast systems.  If we don't do this, a slow drive on a fast
   // system may not set BUSY fast enough and we would think it had
   // completed the command when it really had not even started the
   // command yet.
//printf("ata delay... ");
   ATA_DELAY();
   ATAPI_DELAY( 0 );
   ATAPI_DELAY( 1 );

   // IF
   //    This is an Exec Dev Diag command (cmd=0x90)
   //    and there is no device 0 then
   //    there will be no interrupt. So we must
   //    poll device 1 until it allows register
   //    access and then do normal polling of the Status
   //    register for BSY=0.
   // ELSE
   // IF
   //    This is a Dev Reset command (cmd=0x08) then
   //    there should be no interrupt.  So we must
   //    poll for BSY=0.
   // ELSE
   //    Do the normal wait for interrupt or polling for
   //    completion.

   if ( ( ata->reg_cmd_info.cmd == CMD_EXECUTE_DEVICE_DIAGNOSTIC )
        &&
        ( ata->reg_config_info[0] == REG_CONFIG_TYPE_NONE )
      )
   {
      polled = 1;
      trc_llt( 0, 0, TRC_LLT_PNBSY );
      while ( 1 )
      {
         pio_outbyte( CB_DH, CB_DH_DEV1 | dev75 );
         ATA_DELAY();
         secCnt = pio_inbyte( CB_SC );
         secNum = pio_inbyte( CB_SN );
         if ( ( secCnt == 0x01 ) && ( secNum == 0x01 ) )
            break;
         if ( tmr_chk_timeout() )
         {
            trc_llt( 0, 0, TRC_LLT_TOUT );
            ata->reg_cmd_info.to = 1;
            ata->reg_cmd_info.ec = 24;
            trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
            break;
         }
      }
   }
   else
   {
      if ( ata->reg_cmd_info.cmd == CMD_DEVICE_RESET )
      {
         // Wait for not BUSY -or- wait for time out.
//printf("ata wait busy (reset)... ");

         polled = 1;
         reg_wait_poll( 0, 23 );
      }
      else
      {
         // Wait for interrupt -or- wait for not BUSY -or- wait for time out.

//printf("ata wait... ");
         if ( ! ata->int_use_intr_flag )
            polled = 1;
         reg_wait_poll( 22, 23 );
      }
   }

   // If status was polled or if any error read the status register,
   // otherwise get the status that was read by the interrupt handler.
//printf("ata read status... ");
   if ( ( polled ) || ( ata->reg_cmd_info.ec ) )
      status = pio_inbyte( CB_STAT );
   else
      status = ata->int_ata_status;

   // Error if BUSY, DEVICE FAULT, DRQ or ERROR status now.

   if ( ata->reg_cmd_info.ec == 0 )
   {
      if ( status & ( CB_STAT_BSY | CB_STAT_DF | CB_STAT_DRQ | CB_STAT_ERR ) )
      {
         ata->reg_cmd_info.ec = 21;
         trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
      }
   }

   // read the output registers and trace the command.

   sub_trace_command();

   // BMIDE Error=1?

   if ( sub_readBusMstrStatus() & BM_SR_MASK_ERR )
   {
      ata->reg_cmd_info.ec = 78;                  // yes
      trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
   }

   // NON_DATA_DONE:

   // For interrupt mode, remove interrupt handler.

   int_restore_int_vect();

   // mark end of ND cmd in low level trace

   trc_llt( 0, 0, TRC_LLT_E_ND );

   // All done.  The return values of this function are described in
   // ATAIO.H.
//printf("ata return, ec = %d... ", ata->reg_cmd_info.ec);
   if ( ata->reg_cmd_info.ec )
      return 1;
   return 0;
}

//*************************************************************
//
// reg_non_data_chs() - Execute a non-data command.
//
// Note special handling for Execute Device Diagnostics
// command when there is no device 0.
//
// See ATA-2 Section 9.5, ATA-3 Section 9.5,
// ATA-4 Section 8.8 Figure 12.  Also see Section 8.5.
//
//*************************************************************

int reg_non_data_chs( int dev, int cmd,
                      unsigned int fr, unsigned int sc,
                      unsigned int cyl, unsigned int head, unsigned int sect )

{

   // Setup command parameters.

   sub_zero_return_data();
   ata->reg_cmd_info.flg = TRC_FLAG_ATA;
   ata->reg_cmd_info.ct  = TRC_TYPE_AND;
   ata->reg_cmd_info.cmd = cmd;
   ata->reg_cmd_info.fr1 = fr;
   ata->reg_cmd_info.sc1 = sc;
   ata->reg_cmd_info.sn1 = sect;
   ata->reg_cmd_info.cl1 = cyl & 0x00ff;
   ata->reg_cmd_info.ch1 = ( cyl & 0xff00 ) >> 8;
   ata->reg_cmd_info.dh1 = ( dev ? CB_DH_DEV1 : CB_DH_DEV0 ) | ( head & 0x0f );
   ata->reg_cmd_info.dc1 = ata->int_use_intr_flag ? 0 : CB_DC_NIEN;
   ata->reg_cmd_info.ns  = sc;
   ata->reg_cmd_info.lbaSize = LBACHS;

   // Execute the command.

   return exec_non_data_cmd( dev );
}

//*************************************************************
//
// reg_non_data_lba28() - Easy way to execute a non-data command
//                        using an LBA sector address.
//
//*************************************************************

int reg_non_data_lba28( int dev, int cmd,
                        unsigned int fr, unsigned int sc,
                        unsigned long lba )

{

   // Setup current command information.

   sub_zero_return_data();
   ata->reg_cmd_info.flg = TRC_FLAG_ATA;
   ata->reg_cmd_info.ct  = TRC_TYPE_AND;
   ata->reg_cmd_info.cmd = cmd;
   ata->reg_cmd_info.fr1 = fr;
   ata->reg_cmd_info.sc1 = sc;
   ata->reg_cmd_info.dh1 = CB_DH_LBA | (dev ? CB_DH_DEV1 : CB_DH_DEV0 );
   ata->reg_cmd_info.dc1 = ata->int_use_intr_flag ? 0 : CB_DC_NIEN;
   ata->reg_cmd_info.ns  = sc;
   ata->reg_cmd_info.lbaSize = LBA28;
   ata->reg_cmd_info.lbaHigh1 = 0L;
   ata->reg_cmd_info.lbaLow1 = lba;

   // Execute the command.

   return exec_non_data_cmd( dev );
}

//*************************************************************
//
// reg_non_data_lba48() - Easy way to execute a non-data command
//                        using an LBA sector address.
//
//*************************************************************

int reg_non_data_lba48( int dev, int cmd,
                        unsigned int fr, unsigned int sc,
                        unsigned long lbahi, unsigned long lbalo )

{

   // Setup current command infomation.

   sub_zero_return_data();
   ata->reg_cmd_info.flg = TRC_FLAG_ATA;
   ata->reg_cmd_info.ct  = TRC_TYPE_AND;
   ata->reg_cmd_info.cmd = cmd;
   ata->reg_cmd_info.fr1 = fr;
   ata->reg_cmd_info.sc1 = sc;
   ata->reg_cmd_info.dh1 = CB_DH_LBA | (dev ? CB_DH_DEV1 : CB_DH_DEV0 );
   ata->reg_cmd_info.dc1 = ata->int_use_intr_flag ? 0 : CB_DC_NIEN;
   ata->reg_cmd_info.ns  = sc;
   ata->reg_cmd_info.lbaSize = LBA48;
   ata->reg_cmd_info.lbaHigh1 = lbahi;
   ata->reg_cmd_info.lbaLow1 = lbalo;

   // Execute the command.

   return exec_non_data_cmd( dev );
}

//*************************************************************
//
// exec_pio_data_in_cmd() - Execute a PIO Data In command.
//
// See ATA-2 Section 9.3, ATA-3 Section 9.3,
// ATA-4 Section 8.6 Figure 10.
//
//*************************************************************

static int exec_pio_data_in_cmd( int dev,
                                 //unsigned int seg, unsigned int off,
                                 void *addr,
                            long numSect, int multiCnt )

{
   unsigned char status;
   long wordCnt;
   //unsigned int saveSeg = seg;
   //unsigned int saveOff = off;
   void *saveAddr = addr;

   // mark start of PDI cmd in low level trace

   trc_llt( 0, 0, TRC_LLT_S_PDI );

   // reset Bus Master Error bit

   sub_writeBusMstrStatus( BM_SR_MASK_ERR );

   // Set command time out.

   tmr_set_timeout();

   // Select the drive - call the sub_select function.
   // Quit now if this fails.

   if ( sub_select( dev ) )
   {
      sub_trace_command();
      trc_llt( 0, 0, TRC_LLT_E_PDI );
      ata->reg_drq_block_call_back = (void *) 0;
      return 1;
   }

   // Set up all the registers except the command register.

   sub_setup_command();

   // For interrupt mode, install interrupt handler.

   int_save_int_vect();

   // Start the command by setting the Command register.  The drive
   // should immediately set BUSY status.

   pio_outbyte( CB_CMD, ata->reg_cmd_info.cmd );

   // Waste some time by reading the alternate status a few times.
   // This gives the drive time to set BUSY in the status register on
   // really fast systems.  If we don't do this, a slow drive on a fast
   // system may not set BUSY fast enough and we would think it had
   // completed the command when it really had not even started the
   // command yet.

   ATA_DELAY();

   // Loop to read each sector.

   while ( 1 )
   {
      // READ_LOOP:
      //
      // NOTE NOTE NOTE ...  The primary status register (1f7) MUST NOT be
      // read more than ONCE for each sector transferred!  When the
      // primary status register is read, the drive resets IRQ 14.  The
      // alternate status register (3f6) can be read any number of times.
      // After interrupt read the the primary status register ONCE
      // and transfer the 256 words (REP INSW).  AS SOON as BOTH the
      // primary status register has been read AND the last of the 256
      // words has been read, the drive is allowed to generate the next
      // IRQ 14 (newer and faster drives could generate the next IRQ 14 in
      // 50 microseconds or less).  If the primary status register is read
      // more than once, there is the possibility of a race between the
      // drive and the software and the next IRQ 14 could be reset before
      // the system interrupt controller sees it.

      // Wait for interrupt -or- wait for not BUSY -or- wait for time out.

      ATAPI_DELAY( dev );
      reg_wait_poll( 34, 35 );

      // If polling or error read the status, otherwise
      // get the status that was read by the interrupt handler.

      if ( ( ! ata->int_use_intr_flag ) || ( ata->reg_cmd_info.ec ) )
         status = pio_inbyte( CB_STAT );
      else
         status = ata->int_ata_status;

      // If there was a time out error, go to READ_DONE.

      if ( ata->reg_cmd_info.ec )
         break;   // go to READ_DONE

      // If BSY=0 and DRQ=1, transfer the data,
      // even if we find out there is an error later.

      if ( ( status & ( CB_STAT_BSY | CB_STAT_DRQ ) ) == CB_STAT_DRQ )
      {
         // do the slow data transfer thing

         if ( ata->reg_slow_xfer_flag )
         {
            if ( numSect <= ata->reg_slow_xfer_flag )
            {
               tmr_delay_xfer();
               ata->reg_slow_xfer_flag = 0;
            }
         }

         // increment number of DRQ packets

         ata->reg_cmd_info.drqPackets ++ ;

         // determine the number of sectors to transfer

         wordCnt = multiCnt ? multiCnt : 1;
         if ( wordCnt > numSect )
            wordCnt = numSect;
         wordCnt = wordCnt * 256;

         // Quit if buffer overrun.
         // Adjust buffer address when DRQ block call back in use.

         if ( ata->reg_drq_block_call_back )
         {
            if ( ( wordCnt << 1 ) > ata->reg_buffer_size )
            {
               ata->reg_cmd_info.ec = 61;
               trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
               break;   // go to READ_DONE
            }
            //seg = saveSeg;
            //off = saveOff;
            addr = saveAddr;
         }
         else
         {
            if ( ( ata->reg_cmd_info.totalBytesXfer + ( wordCnt << 1 ) )
                 > ata->reg_buffer_size )
            {
               ata->reg_cmd_info.ec = 61;
               trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
               break;   // go to READ_DONE
            }
         }

         // Do the REP INSW to read the data for one DRQ block.

         ata->reg_cmd_info.totalBytesXfer += ( wordCnt << 1 );
         pio_drq_block_in( CB_DATA, addr, wordCnt );

         ATA_DELAY();   // delay so device can get the status updated

         // Note: The drive should have dropped DATA REQUEST by now.  If there
         // are more sectors to transfer, BUSY should be active now (unless
         // there is an error).

         // Call DRQ block call back function.
         if ( ata->reg_drq_block_call_back )
         {
            ata->reg_cmd_info.drqPacketSize = ( wordCnt << 1 );
            (* ata->reg_drq_block_call_back) ( & ata->reg_cmd_info );
         }

         // Decrement the count of sectors to be transferred
         // and increment buffer address.

         numSect = numSect - ( multiCnt ? multiCnt : 1 );
         //seg = seg + ( 32 * ( multiCnt ? multiCnt : 1 ) );
         addr += 512 * ( multiCnt ? multiCnt : 1 );
      }

      // So was there any error condition?

      if ( status & ( CB_STAT_BSY | CB_STAT_DF | CB_STAT_ERR ) )
      {
         ata->reg_cmd_info.ec = 31;
         trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
         break;   // go to READ_DONE
      }

      // DRQ should have been set -- was it?

      if ( ( status & CB_STAT_DRQ ) == 0 )
      {
         ata->reg_cmd_info.ec = 32;
         trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
         break;   // go to READ_DONE
      }

      // If all of the requested sectors have been transferred, make a
      // few more checks before we exit.

      if ( numSect < 1 )
      {
         // Since the drive has transferred all of the requested sectors
         // without error, the drive should not have BUSY, DEVICE FAULT,
         // DATA REQUEST or ERROR active now.

         ATAPI_DELAY( dev );
         status = pio_inbyte( CB_STAT );
         if ( status & ( CB_STAT_BSY | CB_STAT_DF | CB_STAT_DRQ | CB_STAT_ERR ) )
         //if ( status & ( CB_STAT_BSY | CB_STAT_DF | CB_STAT_ERR ) )
         {
            ata->reg_cmd_info.ec = 33;
            trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
            break;   // go to READ_DONE
         }

         // All sectors have been read without error, go to READ_DONE.

         break;   // go to READ_DONE

      }

      // This is the end of the read loop.  If we get here, the loop is
      // repeated to read the next sector.  Go back to READ_LOOP.

   }

   // read the output registers and trace the command.

   sub_trace_command();

   // BMIDE Error=1?

   if ( sub_readBusMstrStatus() & BM_SR_MASK_ERR )
   {
      ata->reg_cmd_info.ec = 78;                  // yes
      trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
   }

   // READ_DONE:

   // For interrupt mode, remove interrupt handler.

   int_restore_int_vect();

   // mark end of PDI cmd in low level trace

   trc_llt( 0, 0, TRC_LLT_E_PDI );

   // reset ata->reg_drq_block_call_back to NULL (0)

   ata->reg_drq_block_call_back = (void *) 0;

   // All done.  The return values of this function are described in
   // ATAIO.H.

   if ( ata->reg_cmd_info.ec )
      return 1;
   return 0;
}

#if 0
//*************************************************************
//
// reg_pio_data_in_chs() - Execute a PIO Data In command.
//
// See ATA-2 Section 9.3, ATA-3 Section 9.3,
// ATA-4 Section 8.6 Figure 10.
//
//*************************************************************

int reg_pio_data_in_chs( int dev, int cmd,
                         unsigned int fr, unsigned int sc,
                         unsigned int cyl, unsigned int head, unsigned int sect,
                         unsigned int seg, unsigned int off,
                         long numSect, int multiCnt )

{

   // Reset error return data.

   sub_zero_return_data();
   ata->reg_cmd_info.flg = TRC_FLAG_ATA;
   ata->reg_cmd_info.ct  = TRC_TYPE_APDI;
   ata->reg_cmd_info.cmd = cmd;
   ata->reg_cmd_info.fr1 = fr;
   ata->reg_cmd_info.sc1 = sc;
   ata->reg_cmd_info.sn1 = sect;
   ata->reg_cmd_info.cl1 = cyl & 0x00ff;
   ata->reg_cmd_info.ch1 = ( cyl & 0xff00 ) >> 8;
   ata->reg_cmd_info.dh1 = ( dev ? CB_DH_DEV1 : CB_DH_DEV0 ) | ( head & 0x0f );
   ata->reg_cmd_info.dc1 = ata->int_use_intr_flag ? 0 : CB_DC_NIEN;
   ata->reg_cmd_info.lbaSize = LBACHS;

   // these commands transfer only 1 sector
   if (    ( cmd == CMD_IDENTIFY_DEVICE )
        || ( cmd == CMD_IDENTIFY_DEVICE_PACKET )
      )
      numSect = 1;

   // adjust multiple count
   if ( multiCnt & 0x0800 )
   {
      // assume caller knows what they are doing
      multiCnt &= 0x00ff;
   }
   else
   {
      // only multiple commands use multiCnt
      if (    ( cmd != CMD_READ_MULTIPLE )
           && ( cmd != CMD_READ_MULTIPLE_EXT )
         )
         multiCnt = 1;
   }

   ata->reg_cmd_info.ns  = numSect;
   ata->reg_cmd_info.mc  = multiCnt;

   return exec_pio_data_in_cmd( dev, seg, off, numSect, multiCnt );
}
#endif

//*************************************************************
//
// reg_pio_data_in_lba28() - Easy way to execute a PIO Data In command
//                           using an LBA sector address.
//
//*************************************************************

int reg_pio_data_in_lba28( int dev, int cmd,
                           unsigned int fr, unsigned int sc,
                           unsigned long lba,
                           void *addr,
                           long numSect, int multiCnt )

{

   // Reset error return data.

   sub_zero_return_data();
   ata->reg_cmd_info.flg = TRC_FLAG_ATA;
   ata->reg_cmd_info.ct  = TRC_TYPE_APDI;
   ata->reg_cmd_info.cmd = cmd;
   ata->reg_cmd_info.fr1 = fr;
   ata->reg_cmd_info.sc1 = sc;
   ata->reg_cmd_info.dh1 = CB_DH_LBA | (dev ? CB_DH_DEV1 : CB_DH_DEV0 );
   ata->reg_cmd_info.dc1 = ata->int_use_intr_flag ? 0 : CB_DC_NIEN;
   ata->reg_cmd_info.lbaSize = LBA28;
   ata->reg_cmd_info.lbaHigh1 = 0L;
   ata->reg_cmd_info.lbaLow1 = lba;

   // these commands transfer only 1 sector
   if (    ( cmd == CMD_IDENTIFY_DEVICE )
        || ( cmd == CMD_IDENTIFY_DEVICE_PACKET )
      )
      numSect = 1;

   // adjust multiple count
   if ( multiCnt & 0x0800 )
   {
      // assume caller knows what they are doing
      multiCnt &= 0x00ff;
   }
   else
   {
      // only multiple commands use multiCnt
      if (    ( cmd != CMD_READ_MULTIPLE )
           && ( cmd != CMD_READ_MULTIPLE_EXT )
         )
         multiCnt = 1;
   }

   ata->reg_cmd_info.ns  = numSect;
   ata->reg_cmd_info.mc  = multiCnt;

   return exec_pio_data_in_cmd( dev, addr, numSect, multiCnt );
}
//*************************************************************
//
// reg_pio_data_in_lba48() - Easy way to execute a PIO Data In command
//                           using an LBA sector address.
//
//*************************************************************

int reg_pio_data_in_lba48( int dev, int cmd,
                           unsigned int fr, unsigned int sc,
                           unsigned long lbahi, unsigned long lbalo,
                           //unsigned int seg, unsigned int off,
                           void *addr,
                           long numSect, int multiCnt )

{

   // Reset error return data.

   sub_zero_return_data();
   ata->reg_cmd_info.flg = TRC_FLAG_ATA;
   ata->reg_cmd_info.ct  = TRC_TYPE_APDI;
   ata->reg_cmd_info.cmd = cmd;
   ata->reg_cmd_info.fr1 = fr;
   ata->reg_cmd_info.sc1 = sc;
   ata->reg_cmd_info.dh1 = CB_DH_LBA | (dev ? CB_DH_DEV1 : CB_DH_DEV0 );
   ata->reg_cmd_info.dc1 = ata->int_use_intr_flag ? 0 : CB_DC_NIEN;
   ata->reg_cmd_info.lbaSize = LBA48;
   ata->reg_cmd_info.lbaHigh1 = lbahi;
   ata->reg_cmd_info.lbaLow1 = lbalo;

   // adjust multiple count
   if ( multiCnt & 0x0800 )
   {
      // assume caller knows what they are doing
      multiCnt &= 0x00ff;
   }
   else
   {
      // only multiple commands use multiCnt
      if (    ( cmd != CMD_READ_MULTIPLE )
           && ( cmd != CMD_READ_MULTIPLE_EXT )
         )
         multiCnt = 1;
   }

   ata->reg_cmd_info.ns  = numSect;
   ata->reg_cmd_info.mc  = multiCnt;

   return exec_pio_data_in_cmd( dev, addr, numSect, multiCnt );
}

//*************************************************************
//
// exec_pio_data_out_cmd() - Execute a PIO Data Out command.
//
// See ATA-2 Section 9.4, ATA-3 Section 9.4,
// ATA-4 Section 8.7 Figure 11.
//
//*************************************************************

static int exec_pio_data_out_cmd( int dev,
                                  //unsigned int seg, unsigned int off,
                                  void *addr,
                             long numSect, int multiCnt )

{
   unsigned char status;
   int loopFlag = 1;
   long wordCnt;
   //unsigned int saveSeg = seg;
   //unsigned int saveOff = off;
   void *saveAddr = addr;

   // mark start of PDO cmd in low level trace

   trc_llt( 0, 0, TRC_LLT_S_PDO );

   // reset Bus Master Error bit

   sub_writeBusMstrStatus( BM_SR_MASK_ERR );

   // Set command time out.

   tmr_set_timeout();

   // Select the drive - call the sub_select function.
   // Quit now if this fails.

   if ( sub_select( dev ) )
   {
      sub_trace_command();
      trc_llt( 0, 0, TRC_LLT_E_PDO );
      ata->reg_drq_block_call_back = (void *) 0;
      return 1;
   }

   // Set up all the registers except the command register.

   sub_setup_command();

   // For interrupt mode, instal interrupt handler.

   int_save_int_vect();

   // Start the command by setting the Command register.  The drive
   // should immediately set BUSY status.

   pio_outbyte( CB_CMD, ata->reg_cmd_info.cmd );

   // Waste some time by reading the alternate status a few times.
   // This gives the drive time to set BUSY in the status register on
   // really fast systems.  If we don't do this, a slow drive on a fast
   // system may not set BUSY fast enough and we would think it had
   // completed the command when it really had not even started the
   // command yet.

   ATA_DELAY();
   ATAPI_DELAY( dev );

   // Wait for not BUSY or time out.
   // Note: No interrupt is generated for the
   // first sector of a write command.  Well...
   // that's not really true we are working with
   // a PCMCIA PC Card ATA device.

   trc_llt( 0, 0, TRC_LLT_PNBSY );
   while ( 1 )
   {
      status = pio_inbyte( CB_ASTAT );
      if ( ( status & CB_STAT_BSY ) == 0 )
         break;
      if ( tmr_chk_timeout() )
      {
         trc_llt( 0, 0, TRC_LLT_TOUT );
         ata->reg_cmd_info.to = 1;
         ata->reg_cmd_info.ec = 47;
         trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
         loopFlag = 0;
         break;
      }
   }

   // If we are using interrupts and we just got an interrupt, this is
   // wrong.  The drive must not generate an interrupt at this time.

   if ( loopFlag && ata->int_use_intr_flag && ata->int_intr_flag )
   {
      ata->reg_cmd_info.ec = 46;
      trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
      loopFlag = 0;
   }

   // This loop writes each sector.

   while ( loopFlag )
   {
      // WRITE_LOOP:
      //
      // NOTE NOTE NOTE ...  The primary status register (1f7) MUST NOT be
      // read more than ONCE for each sector transferred!  When the
      // primary status register is read, the drive resets IRQ 14.  The
      // alternate status register (3f6) can be read any number of times.
      // For correct results, transfer the 256 words (REP OUTSW), wait for
      // interrupt and then read the primary status register.  AS
      // SOON as BOTH the primary status register has been read AND the
      // last of the 256 words has been written, the drive is allowed to
      // generate the next IRQ 14 (newer and faster drives could generate
      // the next IRQ 14 in 50 microseconds or less).  If the primary
      // status register is read more than once, there is the possibility
      // of a race between the drive and the software and the next IRQ 14
      // could be reset before the system interrupt controller sees it.

      // If BSY=0 and DRQ=1, transfer the data,
      // even if we find out there is an error later.

      if ( ( status & ( CB_STAT_BSY | CB_STAT_DRQ ) ) == CB_STAT_DRQ )
      {
         // do the slow data transfer thing

         if ( ata->reg_slow_xfer_flag )
         {
            if ( numSect <= ata->reg_slow_xfer_flag )
            {
               tmr_delay_xfer();
               ata->reg_slow_xfer_flag = 0;
            }
         }

         // increment number of DRQ packets

         ata->reg_cmd_info.drqPackets ++ ;

         // determine the number of sectors to transfer

         wordCnt = multiCnt ? multiCnt : 1;
         if ( wordCnt > numSect )
            wordCnt = numSect;
         wordCnt = wordCnt * 256;

         // Quit if buffer overrun.
         // If DRQ call back in use:
         // a) Call DRQ block call back function.
         // b) Adjust buffer address.

         if ( ata->reg_drq_block_call_back )
         {
            if ( ( wordCnt << 1 ) > ata->reg_buffer_size )
            {
               ata->reg_cmd_info.ec = 61;
               trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
               break;   // go to READ_DONE
            }
            ata->reg_cmd_info.drqPacketSize = ( wordCnt << 1 );
            (* ata->reg_drq_block_call_back) ( & ata->reg_cmd_info );
            //seg = saveSeg;
            //off = saveOff;
            addr = saveAddr;
         }
         else
         {
            if ( ( ata->reg_cmd_info.totalBytesXfer + ( wordCnt << 1 ) )
                > ata->reg_buffer_size )
            {
               ata->reg_cmd_info.ec = 61;
               trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
               break;   // go to READ_DONE
            }
         }

         // Do the REP OUTSW to write the data for one DRQ block.

         ata->reg_cmd_info.totalBytesXfer += ( wordCnt << 1 );
         pio_drq_block_out( CB_DATA, addr, wordCnt );

         ATA_DELAY();   // delay so device can get the status updated

         // Note: The drive should have dropped DATA REQUEST and
         // raised BUSY by now.

         // Decrement the count of sectors to be transferred
         // and increment buffer address.

         numSect = numSect - ( multiCnt ? multiCnt : 1 );
         //seg = seg + ( 32 * ( multiCnt ? multiCnt : 1 ) );
         addr += 512 * ( multiCnt ? multiCnt : 1 );
      }

      // So was there any error condition?

      if ( status & ( CB_STAT_BSY | CB_STAT_DF | CB_STAT_ERR ) )
      {
         ata->reg_cmd_info.ec = 41;
         trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
         break;   // go to WRITE_DONE
      }

      // DRQ should have been set -- was it?

      if ( ( status & CB_STAT_DRQ ) == 0 )
      {
         ata->reg_cmd_info.ec = 42;
         trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
         break;   // go to WRITE_DONE
      }

      // Wait for interrupt -or- wait for not BUSY -or- wait for time out.

      ATAPI_DELAY( dev );
      reg_wait_poll( 44, 45 );

      // If polling or error read the status, otherwise
      // get the status that was read by the interrupt handler.

      if ( ( ! ata->int_use_intr_flag ) || ( ata->reg_cmd_info.ec ) )
         status = pio_inbyte( CB_STAT );
      else
         status = ata->int_ata_status;

      // If there was a time out error, go to WRITE_DONE.

      if ( ata->reg_cmd_info.ec )
         break;   // go to WRITE_DONE

      // If all of the requested sectors have been transferred, make a
      // few more checks before we exit.

      if ( numSect < 1 )
      {
         // Since the drive has transferred all of the sectors without
         // error, the drive MUST not have BUSY, DEVICE FAULT, DATA REQUEST
         // or ERROR status at this time.

         if ( status & ( CB_STAT_BSY | CB_STAT_DF | CB_STAT_DRQ | CB_STAT_ERR ) )
         {
            ata->reg_cmd_info.ec = 43;
            trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
            break;   // go to WRITE_DONE
         }

         // All sectors have been written without error, go to WRITE_DONE.

         break;   // go to WRITE_DONE

      }

      //
      // This is the end of the write loop.  If we get here, the loop
      // is repeated to write the next sector.  Go back to WRITE_LOOP.

   }

   // read the output registers and trace the command.

   sub_trace_command();

   // BMIDE Error=1?

   if ( sub_readBusMstrStatus() & BM_SR_MASK_ERR )
   {
      ata->reg_cmd_info.ec = 78;                  // yes
      trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
   }

   // WRITE_DONE:

   // For interrupt mode, remove interrupt handler.

   int_restore_int_vect();

   // mark end of PDO cmd in low level trace

   trc_llt( 0, 0, TRC_LLT_E_PDO );

   // reset ata->reg_drq_block_call_back to NULL (0)

   ata->reg_drq_block_call_back = (void *) 0;

   // All done.  The return values of this function are described in
   // ATAIO.H.

   if ( ata->reg_cmd_info.ec )
      return 1;
   return 0;
}

#if 0
//*************************************************************
//
// reg_pio_data_out_chs() - Execute a PIO Data Out command.
//
// See ATA-2 Section 9.4, ATA-3 Section 9.4,
// ATA-4 Section 8.7 Figure 11.
//
//*************************************************************

int reg_pio_data_out_chs( int dev, int cmd,
                          unsigned int fr, unsigned int sc,
                          unsigned int cyl, unsigned int head, unsigned int sect,
                          unsigned int seg, unsigned int off,
                          long numSect, int multiCnt )

{

   // Reset error return data.

   sub_zero_return_data();
   ata->reg_cmd_info.flg = TRC_FLAG_ATA;
   ata->reg_cmd_info.ct  = TRC_TYPE_APDO;
   ata->reg_cmd_info.cmd = cmd;
   ata->reg_cmd_info.fr1 = fr;
   ata->reg_cmd_info.sc1 = sc;
   ata->reg_cmd_info.sn1 = sect;
   ata->reg_cmd_info.cl1 = cyl & 0x00ff;
   ata->reg_cmd_info.ch1 = ( cyl & 0xff00 ) >> 8;
   ata->reg_cmd_info.dh1 = ( dev ? CB_DH_DEV1 : CB_DH_DEV0 ) | ( head & 0x0f );
   ata->reg_cmd_info.dc1 = ata->int_use_intr_flag ? 0 : CB_DC_NIEN;
   ata->reg_cmd_info.lbaSize = LBACHS;

   // adjust multiple count
   if ( multiCnt & 0x0800 )
   {
      // assume caller knows what they are doing
      multiCnt &= 0x00ff;
   }
   else
   {
      // only multiple commands use multiCnt
      if (    ( cmd != CMD_CFA_WRITE_MULTIPLE_WO_ERASE )
           && ( cmd != CMD_WRITE_MULTIPLE )
           && ( cmd != CMD_WRITE_MULTIPLE_EXT )
           && ( cmd != CMD_WRITE_MULTIPLE_FUA_EXT )
         )
         multiCnt = 1;
   }

   ata->reg_cmd_info.ns  = numSect;
   ata->reg_cmd_info.mc  = multiCnt;

   return exec_pio_data_out_cmd( dev, seg, off, numSect, multiCnt );
}

//*************************************************************
//
// reg_pio_data_out_lba28() - Easy way to execute a PIO Data In command
//                            using an LBA sector address.
//
//*************************************************************
#endif

int reg_pio_data_out_lba28( int dev, int cmd,
                            unsigned int fr, unsigned int sc,
                            unsigned long lba,
                            //unsigned int seg, unsigned int off,
                            void *addr,
                            long numSect, int multiCnt )

{

   // Reset error return data.

   sub_zero_return_data();
   ata->reg_cmd_info.flg = TRC_FLAG_ATA;
   ata->reg_cmd_info.ct  = TRC_TYPE_APDO;
   ata->reg_cmd_info.cmd = cmd;
   ata->reg_cmd_info.fr1 = fr;
   ata->reg_cmd_info.sc1 = sc;
   ata->reg_cmd_info.dh1 = CB_DH_LBA | (dev ? CB_DH_DEV1 : CB_DH_DEV0 );
   ata->reg_cmd_info.dc1 = ata->int_use_intr_flag ? 0 : CB_DC_NIEN;
   ata->reg_cmd_info.lbaSize = LBA28;
   ata->reg_cmd_info.lbaHigh1 = 0;
   ata->reg_cmd_info.lbaLow1 = lba;

   // adjust multiple count
   if ( multiCnt & 0x0800 )
   {
      // assume caller knows what they are doing
      multiCnt &= 0x00ff;
   }
   else
   {
      // only multiple commands use multiCnt
      if (    ( cmd != CMD_CFA_WRITE_MULTIPLE_WO_ERASE )
           && ( cmd != CMD_WRITE_MULTIPLE )
           && ( cmd != CMD_WRITE_MULTIPLE_EXT )
           && ( cmd != CMD_WRITE_MULTIPLE_FUA_EXT )
         )
         multiCnt = 1;
   }

   ata->reg_cmd_info.ns  = numSect;
   ata->reg_cmd_info.mc  = multiCnt;

   return exec_pio_data_out_cmd( dev, addr, numSect, multiCnt );
}


//*************************************************************
//
// reg_pio_data_out_lba48() - Easy way to execute a PIO Data In command
//                            using an LBA sector address.
//
//*************************************************************

int reg_pio_data_out_lba48( int dev, int cmd,
                            unsigned int fr, unsigned int sc,
                            unsigned long lbahi, unsigned long lbalo,
                            //unsigned int seg, unsigned int off,
                            void *addr,
                            long numSect, int multiCnt )

{

   // Reset error return data.

   sub_zero_return_data();
   ata->reg_cmd_info.flg = TRC_FLAG_ATA;
   ata->reg_cmd_info.ct  = TRC_TYPE_APDO;
   ata->reg_cmd_info.cmd = cmd;
   ata->reg_cmd_info.fr1 = fr;
   ata->reg_cmd_info.sc1 = sc;
   ata->reg_cmd_info.dh1 = CB_DH_LBA | (dev ? CB_DH_DEV1 : CB_DH_DEV0 );
   ata->reg_cmd_info.dc1 = ata->int_use_intr_flag ? 0 : CB_DC_NIEN;
   ata->reg_cmd_info.lbaSize = LBA48;
   ata->reg_cmd_info.lbaHigh1 = lbahi;
   ata->reg_cmd_info.lbaLow1 = lbalo;

   // adjust multiple count
   if ( multiCnt & 0x0800 )
   {
      // assume caller knows what they are doing
      multiCnt &= 0x00ff;
   }
   else
   {
      // only multiple commands use multiCnt
      if (    ( cmd != CMD_CFA_WRITE_MULTIPLE_WO_ERASE )
           && ( cmd != CMD_WRITE_MULTIPLE )
           && ( cmd != CMD_WRITE_MULTIPLE_EXT )
           && ( cmd != CMD_WRITE_MULTIPLE_FUA_EXT )
         )
         multiCnt = 1;
   }

   ata->reg_cmd_info.ns  = numSect;
   ata->reg_cmd_info.mc  = multiCnt;

   return exec_pio_data_out_cmd( dev, addr, numSect, multiCnt );
}

//*************************************************************
//
// reg_packet() - Execute an ATAPI Packet (A0H) command.
//
// See ATA-4 Section 9.10, Figure 14.
//
//*************************************************************

int reg_packet( int dev,
                unsigned int cpbc,
                //unsigned int cpseg, unsigned int cpoff,
                void *cpAddr,
                int dir,
                long dpbc,
                //unsigned int dpseg, unsigned int dpoff,
                void *dpAddr,
                unsigned long lba )

{
   unsigned char status;
   unsigned char reason;
   unsigned char lowCyl;
   unsigned char highCyl;
   unsigned int byteCnt;
   long wordCnt;
   unsigned int ndx;
   //unsigned long dpaddr;
   void *savedpaddr;
   unsigned char * cfp;
   int slowXferCntr = 0;
   int prevFailBit7 = 0;

   // mark start of PI cmd in low level trace

   trc_llt( 0, 0, TRC_LLT_S_PI );

   // reset Bus Master Error bit

   sub_writeBusMstrStatus( BM_SR_MASK_ERR );

   // Make sure the command packet size is either 12 or 16
   // and save the command packet size and data.

   cpbc = cpbc < 12 ? 12 : cpbc;
   cpbc = cpbc > 12 ? 16 : cpbc;

   // Setup current command information.

   sub_zero_return_data();
   ata->reg_cmd_info.flg = TRC_FLAG_ATAPI;
   ata->reg_cmd_info.ct  = dir ? TRC_TYPE_PPDO : TRC_TYPE_PPDI;
   ata->reg_cmd_info.cmd = CMD_PACKET;
   ata->reg_cmd_info.fr1 = ata->reg_atapi_reg_fr;
   ata->reg_cmd_info.sc1 = ata->reg_atapi_reg_sc;
   ata->reg_cmd_info.sn1 = ata->reg_atapi_reg_sn;
   ata->reg_cmd_info.cl1 = (unsigned char) ( dpbc & 0x00ff );
   ata->reg_cmd_info.ch1 = ( unsigned char) ( ( dpbc & 0xff00 ) >> 8 );
   ata->reg_cmd_info.dh1 = ( dev ? CB_DH_DEV1 : CB_DH_DEV0 )
                      | ( ata->reg_atapi_reg_dh & 0x0f );
   ata->reg_cmd_info.dc1 = ata->int_use_intr_flag ? 0 : CB_DC_NIEN;
   ata->reg_cmd_info.lbaSize = LBA32;
   ata->reg_cmd_info.lbaLow1 = lba;
   ata->reg_cmd_info.lbaHigh1 = 0L;
   ata->reg_atapi_cp_size = cpbc;
   cfp = cpAddr;
   for ( ndx = 0; ndx < cpbc; ndx ++ )
   {
      ata->reg_atapi_cp_data[ndx] = * cfp;
      cfp ++ ;
   }

   // Zero the alternate ATAPI register data.

   ata->reg_atapi_reg_fr = 0;
   ata->reg_atapi_reg_sc = 0;
   ata->reg_atapi_reg_sn = 0;
   ata->reg_atapi_reg_dh = 0;

   // Set command time out.

   tmr_set_timeout();

   // Select the drive - call the sub_select function.
   // Quit now if this fails.

   if ( sub_select( dev ) )
   {
      sub_trace_command();
      trc_llt( 0, 0, TRC_LLT_E_PI );
      ata->reg_drq_block_call_back = (void *) 0;
      return 1;
   }

   // Set up all the registers except the command register.

   sub_setup_command();

   // For interrupt mode, install interrupt handler.

   int_save_int_vect();

   // Start the command by setting the Command register.  The drive
   // should immediately set BUSY status.

   pio_outbyte( CB_CMD, CMD_PACKET );

   // Waste some time by reading the alternate status a few times.
   // This gives the drive time to set BUSY in the status register on
   // really fast systems.  If we don't do this, a slow drive on a fast
   // system may not set BUSY fast enough and we would think it had
   // completed the command when it really had not even started the
   // command yet.

   ATA_DELAY();
   ATAPI_DELAY( dev );

   // Command packet transfer...
   // Check for protocol failures,
   // the device should have BSY=1 or
   // if BSY=0 then either DRQ=1 or CHK=1.

   status = pio_inbyte( CB_ASTAT );
   if ( status & CB_STAT_BSY )
   {
      // BSY=1 is OK
   }
   else
   {
      if ( status & ( CB_STAT_DRQ | CB_STAT_ERR ) )
      {
         // BSY=0 and DRQ=1 is OK
         // BSY=0 and ERR=1 is OK
      }
      else
      {
         ata->reg_cmd_info.failbits |= FAILBIT0;  // not OK
      }
   }

   // Command packet transfer...
   // Poll Alternate Status for BSY=0.

   trc_llt( 0, 0, TRC_LLT_PNBSY );
   while ( 1 )
   {
      status = pio_inbyte( CB_ASTAT );       // poll for not busy
      if ( ( status & CB_STAT_BSY ) == 0 )
         break;
      if ( tmr_chk_timeout() )               // time out yet ?
      {
         trc_llt( 0, 0, TRC_LLT_TOUT );      // yes
         ata->reg_cmd_info.to = 1;
         ata->reg_cmd_info.ec = 51;
         trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
         dir = -1;   // command done
         break;
      }
   }

   // Command packet transfer...
   // Check for protocol failures... no interrupt here please!
   // Clear any interrupt the command packet transfer may have caused.

   if ( ata->int_intr_flag )       // extra interrupt(s) ?
      ata->reg_cmd_info.failbits |= FAILBIT1;
   ata->int_intr_flag = 0;

   // Command packet transfer...
   // If no error, transfer the command packet.

   if ( ata->reg_cmd_info.ec == 0 )
   {

      // Command packet transfer...
      // Read the primary status register and the other ATAPI registers.

      status = pio_inbyte( CB_STAT );
      reason = pio_inbyte( CB_SC );
      lowCyl = pio_inbyte( CB_CL );
      highCyl = pio_inbyte( CB_CH );

      // Command packet transfer...
      // check status: must have BSY=0, DRQ=1 now

      if (    ( status & ( CB_STAT_BSY | CB_STAT_DRQ | CB_STAT_ERR ) )
           != CB_STAT_DRQ
         )
      {
         ata->reg_cmd_info.ec = 52;
         trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
         dir = -1;   // command done
      }
      else
      {
         // Command packet transfer...
         // Check for protocol failures...
         // check: C/nD=1, IO=0.

         if ( ( reason &  ( CB_SC_P_TAG | CB_SC_P_REL | CB_SC_P_IO ) )
              || ( ! ( reason &  CB_SC_P_CD ) )
            )
            ata->reg_cmd_info.failbits |= FAILBIT2;
         if (    ( lowCyl != ata->reg_cmd_info.cl1 )
              || ( highCyl != ata->reg_cmd_info.ch1 ) )
            ata->reg_cmd_info.failbits |= FAILBIT3;

         // Command packet transfer...
         // trace cdb byte 0,
         // xfer the command packet (the cdb)

         trc_llt( 0, * (unsigned char *) cpAddr, TRC_LLT_P_CMD );
         pio_drq_block_out( CB_DATA, cpAddr, cpbc >> 1 );

         ATA_DELAY();   // delay so device can get the status updated
      }
   }

   // Data transfer loop...
   // If there is no error, enter the data transfer loop.
   // First adjust the I/O buffer address so we are able to
   // transfer large amounts of data (more than 64K).

   //dpaddr = dpseg;
   //dpaddr = dpaddr << 4;
   //dpaddr = dpaddr + dpoff;
   savedpaddr = dpAddr;

   while ( ata->reg_cmd_info.ec == 0 )
   {
      // Data transfer loop...
      // Wait for interrupt -or- wait for not BUSY -or- wait for time out.

      ATAPI_DELAY( dev );
      reg_wait_poll( 53, 54 );

      // Data transfer loop...
      // If there was a time out error, exit the data transfer loop.

      if ( ata->reg_cmd_info.ec )
      {
         dir = -1;   // command done
         break;
      }

      // Data transfer loop...
      // If using interrupts get the status read by the interrupt
      // handler, otherwise read the status register.

      if ( ata->int_use_intr_flag )
         status = ata->int_ata_status;
      else
         status = pio_inbyte( CB_STAT );
      reason = pio_inbyte( CB_SC );
      lowCyl = pio_inbyte( CB_CL );
      highCyl = pio_inbyte( CB_CH );

      // Data transfer loop...
      // Exit the read data loop if the device indicates this
      // is the end of the command.

      if ( ( status & ( CB_STAT_BSY | CB_STAT_DRQ ) ) == 0 )
      {
         dir = -1;   // command done
         break;
      }

      // Data transfer loop...
      // The device must want to transfer data...
      // check status: must have BSY=0, DRQ=1 now.

      if ( ( status & ( CB_STAT_BSY | CB_STAT_DRQ ) ) != CB_STAT_DRQ )
      {
         ata->reg_cmd_info.ec = 55;
         trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
         dir = -1;   // command done
         break;
      }
      else
      {
         // Data transfer loop...
         // Check for protocol failures...
         // check: C/nD=0, IO=1 (read) or IO=0 (write).

         if ( ( reason &  ( CB_SC_P_TAG | CB_SC_P_REL ) )
              || ( reason &  CB_SC_P_CD )
            )
            ata->reg_cmd_info.failbits |= FAILBIT4;
         if ( ( reason & CB_SC_P_IO ) && dir )
            ata->reg_cmd_info.failbits |= FAILBIT5;
      }

      // do the slow data transfer thing

      if ( ata->reg_slow_xfer_flag )
      {
         slowXferCntr ++ ;
         if ( slowXferCntr <= ata->reg_slow_xfer_flag )
         {
            tmr_delay_xfer();
            ata->reg_slow_xfer_flag = 0;
         }
      }

      // Data transfer loop...
      // get the byte count, check for zero...

      byteCnt = ( highCyl << 8 ) | lowCyl;
      if ( byteCnt < 1 )
      {
         ata->reg_cmd_info.ec = 59;
         trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
         dir = -1;   // command done
         break;
      }

      // Data transfer loop...
      // and check protocol failures...

      if ( ((long)byteCnt) > dpbc )
         ata->reg_cmd_info.failbits |= FAILBIT6;
      ata->reg_cmd_info.failbits |= prevFailBit7;
      prevFailBit7 = 0;
      if ( byteCnt & 0x0001 )
         prevFailBit7 = FAILBIT7;

      // Data transfer loop...
      // Quit if buffer overrun.
      // If DRQ call back in use adjust buffer address.

      if ( ata->reg_drq_block_call_back )
      {
         if ( ((long)byteCnt) > ata->reg_buffer_size )
         {
            ata->reg_cmd_info.ec = 61;
            trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
            dir = -1;   // command done
            break;
         }
         ata->reg_cmd_info.drqPacketSize = byteCnt;
         dpAddr = savedpaddr;
      }
      else
      {
         if ( ((long)( ata->reg_cmd_info.totalBytesXfer + byteCnt )) > ata->reg_buffer_size )
         {
            ata->reg_cmd_info.ec = 61;
            trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
            dir = -1;   // command done
            break;
         }
      }

      // increment number of DRQ packets

      ata->reg_cmd_info.drqPackets ++ ;

      // Data transfer loop...
      // transfer the data and update the i/o buffer address
      // and the number of bytes transfered.

      wordCnt = ( byteCnt >> 1 ) + ( byteCnt & 0x0001 );
      ata->reg_cmd_info.totalBytesXfer += ( wordCnt << 1 );
      //dpseg = (unsigned int) ( dpaddr >> 4 );
      //dpoff = (unsigned int) ( dpaddr & 0x0000000fL );
      if ( dir )
      {
         if ( ata->reg_drq_block_call_back )
            (* ata->reg_drq_block_call_back) ( & ata->reg_cmd_info );
         pio_drq_block_out( CB_DATA, dpAddr, wordCnt );
      }
      else
      {
         pio_drq_block_in( CB_DATA, dpAddr, wordCnt );
         if ( ata->reg_drq_block_call_back )
            (* ata->reg_drq_block_call_back) ( & ata->reg_cmd_info );
      }
      dpAddr += byteCnt;

      ATA_DELAY();   // delay so device can get the status updated
   }

   // End of command...
   // Wait for interrupt or poll for BSY=0,
   // but don't do this if there was any error or if this
   // was a commmand that did not transfer data.

   if ( ( ata->reg_cmd_info.ec == 0 ) && ( dir >= 0 ) )
   {
      ATAPI_DELAY( dev );
      reg_wait_poll( 56, 57 );
   }

   // Final status check, only if no previous error.

   if ( ata->reg_cmd_info.ec == 0 )
   {
      // Final status check...
      // If using interrupts get the status read by the interrupt
      // handler, otherwise read the status register.

      if ( ata->int_use_intr_flag )
         status = ata->int_ata_status;
      else
         status = pio_inbyte( CB_STAT );
      reason = pio_inbyte( CB_SC );
      lowCyl = pio_inbyte( CB_CL );  (void) lowCyl;
      highCyl = pio_inbyte( CB_CH ); (void) highCyl;

      // Final status check...
      // check for any error.

      if ( status & ( CB_STAT_BSY | CB_STAT_DRQ | CB_STAT_ERR ) )
      {
         ata->reg_cmd_info.ec = 58;
         trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
      }
   }

   // Final status check...
   // Check for protocol failures...
   // check: C/nD=1, IO=1.

   if ( ( reason & ( CB_SC_P_TAG | CB_SC_P_REL ) )
        || ( ! ( reason & CB_SC_P_IO ) )
        || ( ! ( reason & CB_SC_P_CD ) )
      )
      ata->reg_cmd_info.failbits |= FAILBIT8;

   // Done...
   // Read the output registers and trace the command.

   if ( ! ata->reg_cmd_info.totalBytesXfer )
      ata->reg_cmd_info.ct = TRC_TYPE_PND;
   sub_trace_command();

   // Final status check
   // BMIDE Error=1?

   if ( sub_readBusMstrStatus() & BM_SR_MASK_ERR )
   {
      ata->reg_cmd_info.ec = 78;                  // yes
      trc_llt( 0, ata->reg_cmd_info.ec, TRC_LLT_ERROR );
   }

   // For interrupt mode, remove interrupt handler.

   int_restore_int_vect();

   // mark end of PI cmd in low level trace

   trc_llt( 0, 0, TRC_LLT_E_PI );

   // reset ata->reg_drq_block_call_back to NULL (0)

   ata->reg_drq_block_call_back = (void *) 0;

   // All done.  The return values of this function are described in
   // ATAIO.H.

   if ( ata->reg_cmd_info.ec )
      return 1;
   return 0;
}

// end ataioreg.c
#endif // ARCH_ia32
